0 options, 1 programmable relay board, Table 7 programmable relay board pinout – Emerson Liebert Static Transfer Switch User Manual

Options

14

6.0

O

PTIONS

This section discusses the options available for the Liebert STS2. The communications options are

also discussed in 12.0 - Communication Interfaces.

6.1

Programmable Relay Board

The Programmable Relay Board (PRB) provides a means to trigger an external device when an event

occurs in the Liebert STS2. Each PRB has eight channels. Each channel has two sets of Form-C dry

contacts, rated 1 Amp @ 30 VDC or 250 mAmp @ 125VAC.
Any alarm/event can be programmed to any channel or channels. Up to ten (10) events can be pro-

grammed to a relay. If multiple events are grouped to one relay, group the events logically to simplify

troubleshooting when an event is triggered. The same alarm/event can be programmed to more than

one channel. Up to two Programmable Relay Boards can be installed in the Liebert STS2 for a total of

16 channels. Programming is performed through the touch screen display.
See Configuring the Programmable Relay Board Settings on page 97 for default settings and

instructions for reconfiguring the relays. See Figures 21 and 22 for the location of the PRB. See

Figure 24 for wiring details. Table 7 provides the PRB pinout.

6.2

Optimized Transfer

When the Liebert STS2 is used as a primary-side switch—on the primary of an isolation trans-

former—optimized transfer greatly reduces the transformer magnetization current during automatic

transfers through a new transfer control algorithm. The Liebert algorithm (patent pending) optimizes

the transfer timing so that the volt-seconds applied to the downstream transformer primary is bal-

anced, minimizing peak saturation current.
The volt-second balance is achieved by directly computing the volt-second applied to the transformer

during transfer events and determining the optimum time to turn on the alternate source SCRs in

order to balance the volt-second within specified tolerance.
Optimized transfer also seeks to minimize the voltage disturbances while still maintaining trans-

former flux balance. This unique flux balance algorithm does not just wait for the balance point to

occur, but will pulse fire the SCRs as soon as possible to minimize the voltage disruption. This results

in far superior voltage waveforms applied to the load.

Table 7

Programmable relay board pinout

Channel

Pin No.

C

N.C.

N.O.

TB1

CH1

A

1-3

1

2

3

B

4-6

4

5

6

CH2

A

7-9

7

8

9

B

10-12

10

11

12

CH3

A

13-15

13

14

15

TB2

B

1-3

1

2

3

CH4

A

4-6

4

5

6

B

7-9

7

8

9

CH5

A

10-12

10

11

12

B

13-15

13

14

15

TB3

CH6

A

1-3

1

2

3

B

4-6

4

5

6

CH7

A

7-9

7

8

9

B

10-12

10

11

12

CH8

A

13-15

13

14

15

TB4

B

1-3

1

2

3

Key: N.O. = Normally Open; N/C. = Normally Closed; C = Common
Note: Pin 16 not used on TB1, TB2, and TB3.